A Region in the Upper Half-Plane Meeting Each Unimodular Orbit Exactly Once 
A Region in the Upper Half-Plane Meeting Each Unimodular Orbit Exactly Once by IIT Madras / T.E. Venkata Balaji
Video Lecture 43 of 48
Not yet rated
Views: 662
Date Added: January 12, 2015

Lecture Description

Goals of the Lecture: - We prove the fact that a suitable region in the upper half-plane, which was described in the previous lecture and which was shown there to intersect each orbit of the unimodular group, meets each unimodular orbit at precisely one point. All this amounts to showing that the region is indeed a fundamental region for the unimodular group as claimed in the previous lecture Topics: Upper half-plane, quotient by the unimodular group, orbits of the unimodular group, representative of an orbit, invariants for complex tori, complex torus associated to a lattice (or) grid in the plane, doubly-periodic meromorphic function (or) elliptic function associated to a lattice, Weierstrass phe-function associated to a lattice, ordinary differential equation satisfied by the Weierstrass phe-function, automorphic function (or) automorphic form, weight two modular function (or) weight two modular form, full modular function (or) full modular form, period two modular form, congruence-mod-2 normal subgroup of the unimodular group, projective special linear group with mod-2 coefficients, finite group, kernel of a group homomorphism, zeros of the derivative of the Weierstrass phe-function, pole of order two (or) double pole with residue zero, universal cover, neighborhood of infinity, lower half-plane, rational function, kernel of a group homomorphism, functional equations satisfied by the weight two modular form, j-invariant of a complex torus (or) j-invariant of an algebraic elliptic curve, Fundamental theorem of Algebra, complex field is algebraically closed, fundamental region for the full modular form, fundamental region for the unimodular group, ramified (or) branched covering, group-invariant holomorphic maps, fundamental region for a group-invariant holomorphic map, fundamental parallelogram associated to a lattice in the plane, fundamental region associated to the quotient map defining a complex torus.

Course Index

  1. The Idea of a Riemann Surface
  2. Simple Examples of Riemann Surfaces
  3. Maximal Atlases and Holomorphic Maps of Riemann Surfaces
  4. Riemann Surface Structure on a Cylinder
  5. Riemann Surface Structure on a Torus
  6. Riemann Surface Structures on Cylinders and Tori via Covering Spaces
  7. Möbius Transformations Make up Fundamental Groups of Riemann Surfaces
  8. Homotopy and the First Fundamental Group
  9. A First Classification of Riemann Surfaces
  10. The Importance of the Path-lifting Property
  11. Fundamental groups as Fibres of the Universal covering Space
  12. The Monodromy Action
  13. The Universal covering as a Hausdorff Topological Space
  14. The Construction of the Universal Covering Map
  15. Universality of the Universal Covering
  16. The Fundamental Group of the base as the Deck Transformation Group
  17. The Riemann Surface Structure on the Topological Covering of a Riemann Surface
  18. Riemann Surfaces with Universal Covering the Plane or the Sphere
  19. Classifying Complex Cylinders Riemann Surfaces
  20. Möbius Transformations with a Single Fixed Point
  21. Möbius Transformations with Two Fixed Points
  22. Torsion-freeness of the Fundamental Group of a Riemann Surface
  23. Characterizing Riemann Surface Structures on Quotients of the Upper Half
  24. Classifying Annuli up to Holomorphic Isomorphism
  25. Orbits of the Integral Unimodular Group in the Upper Half-Plane
  26. Galois Coverings are precisely Quotients by Properly Discontinuous Free Actions
  27. Local Actions at the Region of Discontinuity of a Kleinian Subgroup
  28. Quotients by Kleinian Subgroups give rise to Riemann Surfaces
  29. The Unimodular Group is Kleinian
  30. The Necessity of Elliptic Functions for the Classification of Complex Tori
  31. The Uniqueness Property of the Weierstrass Phe-function
  32. The First Order Degree Two Cubic Ordinary Differential Equation satisfied by the Weierstrass Phe-function
  33. The Values of the Weierstrass Phe function at the Zeros of its Derivative
  34. The Construction of a Modular Form of Weight Two on the Upper Half-Plane
  35. The Fundamental Functional Equations satisfied by the Modular Form of Weight
  36. The Weight Two Modular Form assumes Real Values on the Imaginary Axis
  37. The Weight Two Modular Form Vanishes at Infinity
  38. The Weight Two Modular Form Decays Exponentially in a Neighbourhood of Infinity
  39. Suitable Restriction of the Weight Two Modular Form is a Holomorphic Conformal Isomorphism onto the Upper Half-Plane
  40. The J-Invariant of a Complex Torus (or) of an Algebraic Elliptic Curve
  41. Fundamental Region in the Upper Half-Plane for the Elliptic Modular J-Invariant
  42. The Fundamental Region in the Upper Half-Plane for the Unimodular Group
  43. A Region in the Upper Half-Plane Meeting Each Unimodular Orbit Exactly Once
  44. Moduli of Elliptic Curves
  45. Punctured Complex Tori are Elliptic Algebraic Affine Plane
  46. The Natural Riemann Surface Structure on an Algebraic Affine Nonsingular Plane Curve
  47. Complex Projective 2-Space as a Compact Complex Manifold of Dimension Two
  48. Complex Tori are the same as Elliptic Algebraic Projective Curves

Course Description

The subject of algebraic curves (equivalently compact Riemann surfaces) has its origins going back to the work of Riemann, Abel, Jacobi, Noether, Weierstrass, Clifford and Teichmueller. It continues to be a source for several hot areas of current research. Its development requires ideas from diverse areas such as analysis, PDE, complex and real differential geometry, algebra---especially commutative algebra and Galois theory, homological algebra, number theory, topology and manifold theory. The course begins by introducing the notion of a Riemann surface followed by examples. Then the classification of Riemann surfaces is achieved on the basis of the fundamental group by the use of covering space theory and uniformisation. This reduces the study of Riemann surfaces to that of subgroups of Moebius transformations. The case of compact Riemann surfaces of genus 1, namely elliptic curves, is treated in detail. The algebraic nature of elliptic curves and a complex analytic construction of the moduli space of elliptic curves is given.

Comments

There are no comments. Be the first to post one.
  Post comment as a guest user.
Click to login or register:
Your name:
Your email:
(will not appear)
Your comment:
(max. 1000 characters)
Are you human? (Sorry)